Potential Energy of a Multiparticle System: Difference between revisions

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  <div style="text-align: center;">
<math>\Delta K_{sys} = W_{surr}</math> =>
<math>\Delta K_{sys} = W_{surr}</math> =>
<math>\Delta K_{ball} + K_{earth} = 0 </math>
<math>\Delta K_{ball} + \Delta K_{earth} = 0 </math>
</div>
</div>
However, it is quite apparent from the experimental observation that the kinetic energy of the ball increased since it acquired speed when dropping, and that the kinetic energy of the Earth also increased in a small amount since the gravitational force between the ball and the Earth drew the Earth towards the ball. In other words, the experimental observation indicates that <math>\Delta K_{ball} > 0</math> and <math>\Delta K_{earth} > 0</math>. This seems to introduce a conflict between a real-world experiment and a fundamental principle in Physics, where the experiment indicates that the kinetic energy of the two-body system (ball + Earth) increased, while the energy principle states that the energy change of the system be zero since no significant work is done by the surroundings on the system. '''This can't be correct!''' One may decide that the fundamental Energy Principle has been violated. But wait! Is it possible that some energy component is overlooked during this process?  
However, it is quite apparent from the experimental observation that the kinetic energy of the ball increased since it acquired speed when dropping, and that the kinetic energy of the Earth also increased in a small amount since the gravitational force between the ball and the Earth drew the Earth towards the ball. In other words, the experimental observation indicates that <math>\Delta K_{ball} > 0</math> and <math>\Delta K_{earth} > 0</math>. This seems to introduce a conflict between a real-world experiment and a fundamental principle in Physics, where the experiment indicates that the kinetic energy of the two-body system (ball + Earth) increased, while the energy principle states that the energy change of the system be zero since no significant work is done by the surroundings on the system. '''This can't be correct!''' One may decide that the fundamental Energy Principle has been violated. But wait! Is it possible that some energy component is overlooked during this process?  


In fact, some energy component is missing from the energy principle for systems that contain more than one interacting object: the potential energy, commonly designated as <math>U</math>. In particular, any system that consists of more than one particle (multiparticle systems) such as the ball-Earth system, compressed/stretched springs, or atoms in which protons and electrons interact electrically, have a type of energy that is associated with the interactions between pairs of particles inside the system. In the ball-Earth system, it is associated with the interaction between the ball and the Earth, and it is different from the rest energies of the ball or the Earth, and different from the kinetic energies of the two individual particles. This specific type of pairwise interaction energy  is referred to as ''potential energy'' for multiparticle systems.   
In fact, some energy component is missing from the energy principle for systems that contain more than one interacting object: the potential energy, commonly designated as <math>U</math>. In particular, any system that consists of more than one particle (multiparticle systems) such as the ball-Earth system, compressed/stretched springs, or atoms in which protons and electrons interact electrically, have a type of energy that is associated with the interactions between pairs of particles inside the system. In the ball-Earth system, it is associated with the interaction between the ball and the Earth, and it is different from the rest energies of the ball or the Earth, and different from the kinetic energies of the two individual particles. This specific type of pairwise interaction energy  is referred to as ''potential energy'' for multiparticle systems.  For this ball-Earth system consisting of the ball and the Earth interacting with each other, the total energy change is in fact:
 
<div style="text-align: center;">
<math>m_{ball}c^2 + m_{Earth}c^2 + \Delta K_{ball} + \Delta K_{earth} + \Delta U_{ball-Earth} = 0 </math>
</div>





Revision as of 22:03, 27 November 2016

Claimed By yzhang637 - 2016 Fall

This wikipage discusses the definition and significance of the potential energy in a multiparticle system, and exemplifies it in different contexts.

The Main Idea

Imagine you drop a ball with a mass of [math]\displaystyle{ M }[/math] near the surface of the earth at the height of [math]\displaystyle{ h }[/math]. If the ball alone is considered to be the system, i.e., the Earth is the surrounding, it is straightforward to find that the kinetic energy of the system (ball) increases, due to the positive work done on the ball by the Earth. In other words, as the gravitational force acts in the same direction as the displacement of the ball, the work done by the surroundings (the Earth) is equal to [math]\displaystyle{ Mgh }[/math].

What if you choose the system to contain both the ball and the Earth? In this case, nothing is significant in the surroundings to exert any work on the system. As a result,

[math]\displaystyle{ \Delta K_{sys} = W_{surr} }[/math] => [math]\displaystyle{ \Delta K_{ball} + \Delta K_{earth} = 0 }[/math]

However, it is quite apparent from the experimental observation that the kinetic energy of the ball increased since it acquired speed when dropping, and that the kinetic energy of the Earth also increased in a small amount since the gravitational force between the ball and the Earth drew the Earth towards the ball. In other words, the experimental observation indicates that [math]\displaystyle{ \Delta K_{ball} \gt 0 }[/math] and [math]\displaystyle{ \Delta K_{earth} \gt 0 }[/math]. This seems to introduce a conflict between a real-world experiment and a fundamental principle in Physics, where the experiment indicates that the kinetic energy of the two-body system (ball + Earth) increased, while the energy principle states that the energy change of the system be zero since no significant work is done by the surroundings on the system. This can't be correct! One may decide that the fundamental Energy Principle has been violated. But wait! Is it possible that some energy component is overlooked during this process?

In fact, some energy component is missing from the energy principle for systems that contain more than one interacting object: the potential energy, commonly designated as [math]\displaystyle{ U }[/math]. In particular, any system that consists of more than one particle (multiparticle systems) such as the ball-Earth system, compressed/stretched springs, or atoms in which protons and electrons interact electrically, have a type of energy that is associated with the interactions between pairs of particles inside the system. In the ball-Earth system, it is associated with the interaction between the ball and the Earth, and it is different from the rest energies of the ball or the Earth, and different from the kinetic energies of the two individual particles. This specific type of pairwise interaction energy is referred to as potential energy for multiparticle systems. For this ball-Earth system consisting of the ball and the Earth interacting with each other, the total energy change is in fact:

[math]\displaystyle{ m_{ball}c^2 + m_{Earth}c^2 + \Delta K_{ball} + \Delta K_{earth} + \Delta U_{ball-Earth} = 0 }[/math]



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